Subepicardial Action Potential Characteristics Are a Function of Depth and Activation Sequence in Isolated Rabbit Hearts

Kelly, Allen; Ghouri, Iffath A.; Kemi, Ole Johan; Bishop, Martin J.; Bernus, Olivier; Fenton, Flavio H.; Myles, Rachel C.; Burton, Francis L.; Smith, Godfrey L.

doi:10.1161/circep.113.000334

Cited by 27 publications

(40 citation statements)

References 45 publications

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“…Recently this relationship was examined in using AP measurements in all 3 dimensions of the myocardium. The study concluded that dV/dtmax was unaffected by propagation direction deep within the myocardium and that AP rise time was a dictated by a balance between INa and the downstream axial current developed by the myocardium [56].…”

Section: β-Adrenergic Signalling In the Heartmentioning

confidence: 99%

β-Adrenergic modulation of myocardial conduction velocity: Connexins vs. sodium current

Campbell

Johnstone

Baillie

et al. 2014

Journal of Molecular and Cellular Cardiology

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Section: β-Adrenergic Signalling In the Heartmentioning

confidence: 99%

β-Adrenergic modulation of myocardial conduction velocity: Connexins vs. sodium current

Campbell

Johnstone

Baillie

et al. 2014

Journal of Molecular and Cellular Cardiology

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“…This is just enough current to excite longitudinally but not transversely, with a partial activation of the fast sodium channel (Boyle et al, 2012). The electrotonic loading is also lower near the boundary due to the boundary condition, so a lower transmembrane current density is required to excite tissue down the concentration gradient (Kelly et al, 2013; Bishop et al, 2014). In addition, the high extracellular conductivity adjacent to the boundary (in the bath space) significantly increases the conduction velocity of the wave close to the surface (Henriquez et al, 1996, 2007; Bishop and Plank, 2011; Bishop et al, 2011).…”

Section: Discussionmentioning

confidence: 99%

Bidomain Predictions of Virtual Electrode-Induced Make and Break Excitations around Blood Vessels

Connolly

Vigmond

Bishop

2017

Front. Bioeng. Biotechnol.

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Introduction and backgroundVirtual electrodes formed by field stimulation during defibrillation of cardiac tissue play an important role in eliciting activations. It has been suggested that the coronary vasculature is an important source of virtual electrodes, especially during low-energy defibrillation. This work aims to further the understanding of how virtual electrodes from the coronary vasculature influence defibrillation outcomes.MethodsUsing the bidomain model, we investigated how field stimulation elicited activations from virtual electrodes around idealized intramural blood vessels. Strength–interval curves, which quantify the stimulus strength required to elicit wavefront propagation from the vessels at different states of tissue refractoriness, were computed for each idealized geometry.ResultsMake excitations occurred at late diastolic intervals, originating from regions of depolarization around the vessel. Break excitations occurred at early diastolic intervals, whereby the vessels were able to excite surrounding refractory tissue due to the local restoration of excitability by virtual electrode-induced hyperpolarizations. Overall, strength–interval curves had similar morphologies and underlying excitation mechanisms compared with previous experimental and numerical unipolar stimulation studies of cardiac tissue. Including the presence of the vessel wall increased the field strength required for make excitations but decreased the field strength required for break excitations, and the field strength at which break excitations occurred was generally greater than 5 V/cm. Finally, in a more realistic ventricular slice geometry, the proximity of virtual electrodes around subepicardial vessels was seen to cause break excitations in the form of propagating unstable wavelets to the subepicardial layer.ConclusionRepresenting the blood vessel wall microstructure in computational bidomain models of defibrillation is recommended as it significantly alters the electrophysiological response of the vessel to field stimulation. Although vessels may facilitate excitation of relatively refractory tissue via break excitations, the field strength required for this is generally greater than those used in the literature on low-energy defibrillation. However, the high-intensity shocks used in standard defibrillation may elicit break excitation propagation from the coronary vasculature.

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“…Firstly, it will provide an essential tool to facilitate a closer, and essential, validation of the predictions made from computational simulation results using these latest highly-detailed MR-based models with optical mapping recordings which, until now, has not been possible. Secondly, it will provide important insight into the underlying mechanisms of fluorescent signal distortion and the role of fine-scale structures, which may be of significant importance in facilitating a better interpretation of optical mapping signals from high-resolution imaging systems (Bub et al, 2010; Kelly et al, 2013). …”

Section: Discussionmentioning

confidence: 99%

“…Many optical mapping studies in recent years have used careful measurements of both upstroke durations and morphologies from the epicardial surface to infer detailed information regarding localized subsurface wavefront direction (Hyatt et al, 2003, 2005) and relative electrotonic loading (Kelly et al, 2013). Although, in this study we highlighted the significantly different effects on the upstroke due to the interaction of the wavefront with large sub-epicardial cavities for different overall global wavefront propagation directions (toward and parallel to the recording surface), the interaction with localized subsurface wavefront orientations with cavities may also represent an important consideration.…”

Section: Discussionmentioning

confidence: 99%

Simulating photon scattering effects in structurally detailed ventricular models using a Monte Carlo approach

Bishop

Plank

2014

Front. Physiol.

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Light scattering during optical imaging of electrical activation within the heart is known to significantly distort the optically-recorded action potential (AP) upstroke, as well as affecting the magnitude of the measured response of ventricular tissue to strong electric shocks. Modeling approaches based on the photon diffusion equation have recently been instrumental in quantifying and helping to understand the origin of the resulting distortion. However, they are unable to faithfully represent regions of non-scattering media, such as small cavities within the myocardium which are filled with perfusate during experiments. Stochastic Monte Carlo (MC) approaches allow simulation and tracking of individual photon “packets” as they propagate through tissue with differing scattering properties. Here, we present a novel application of the MC method of photon scattering simulation, applied for the first time to the simulation of cardiac optical mapping signals within unstructured, tetrahedral, finite element computational ventricular models. The method faithfully allows simulation of optical signals over highly-detailed, anatomically-complex MR-based models, including representations of fine-scale anatomy and intramural cavities. We show that optical action potential upstroke is prolonged close to large subepicardial vessels than further away from vessels, at times having a distinct “humped” morphology. Furthermore, we uncover a novel mechanism by which photon scattering effects around vessels cavities interact with “virtual-electrode” regions of strong de-/hyper-polarized tissue surrounding cavities during shocks, significantly reducing the apparent optically-measured epicardial polarization. We therefore demonstrate the importance of this novel optical mapping simulation approach along with highly anatomically-detailed models to fully investigate electrophysiological phenomena driven by fine-scale structural heterogeneity.

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Subepicardial Action Potential Characteristics Are a Function of Depth and Activation Sequence in Isolated Rabbit Hearts

Cited by 27 publications

References 45 publications

β-Adrenergic modulation of myocardial conduction velocity: Connexins vs. sodium current

β-Adrenergic modulation of myocardial conduction velocity: Connexins vs. sodium current

Bidomain Predictions of Virtual Electrode-Induced Make and Break Excitations around Blood Vessels

Simulating photon scattering effects in structurally detailed ventricular models using a Monte Carlo approach

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